A comprehensive index for assessing environmental stress in animals.

Numerous models and indices exist that attempt to characterize the effect of environmental factors on the comfort of animals and humans. Heat and cold indices have been utilized to adjust ambient temperature (Ta) for the effects of relative humidity (RH) or wind speed (WS) or both for the purposes of obtaining a "feels-like" or apparent temperature. However, no model has been found that incorporates adjustments for RH, WS, and radiation (RAD) over conditions that encompass hot and cold environmental conditions. The objective of this study was to develop a comprehensive climate index (CCI) that has application under a wide range of environmental conditions and provides an adjustment to Ta for RH, WS, and RAD. Environmental data were compiled from 9 separate summer periods in which heat stress events occurred and from 6 different winter periods to develop and validate the CCI. The RH adjustment is derived from an exponential relationship between Ta and RH with temperature being adjusted up or down from an RH value of 30%. At 45 degrees C, the temperature adjustment for increasing RH from 30 to 100% equals approximately 16 degrees C, whereas at -30 degrees C temperature adjustments due to increasing RH from 30 to 100% equal approximately -3.0 degrees C, with greater RH values contributing to a reduced apparent temperature under cold conditions. The relationship between WS and temperature adjustments was also determined to be exponential with a logarithmic adjustment to define appropriate declines in apparent temperature as WS increases. With this index, slower WS results in the greatest change in apparent temperature per unit of WS regardless of whether hot or cold conditions exist. As WS increases, the change in apparent temperature per unit of WS becomes less. Based on existing windchill and heat indices, the effect of WS on apparent temperature is sufficiently similar to allow one equation to be utilized under hot and cold conditions. The RAD component was separated into direct solar radiation and ground surface radiation. Both of these were found to have a linear relationship with Ta. This index will be useful for further development of biological response functions, which are associated with energy exchange, and improving decision-making processes, which are weather-dependent. In addition, the defined thresholds can serve as management and environmental mitigation guidelines to protect and ensure animal comfort.

[1]  T. Tylutki,et al.  Accounting for the effects of environment on the nutrient requirements of dairy cattle. , 1998, Journal of dairy science.

[2]  A. Webster Direct effects of cold weather on the energetic efficiency of beef production in different regions of Canada. , 1970 .

[3]  G L Hahn,et al.  Feeding strategies for managing heat load in feedlot cattle. , 2002, Journal of animal science.

[4]  J. Bligh,et al.  Energy Balance and Temperature Regulation , 1984 .

[5]  T. Mader,et al.  A new heat load index for feedlot cattle. , 2008, Journal of animal science.

[6]  D. E. Buffington,et al.  Black Globe-Humidity Index (BGHI) as Comfort Equation for Dairy Cows , 1981 .

[7]  T. Mader Environmental stress in confined beef cattle , 2003 .

[8]  T. E. Bond,et al.  Thermal design of livestock shades , 1950 .

[9]  T. Mader,et al.  Environmental factors influencing heat stress in feedlot cattle. , 2006, Journal of animal science.

[10]  Rodrigo A. Arias Modeling the effects of environmental factors on finished cattle , 2008 .

[11]  T. Mader,et al.  Heat tolerance of Boran and Tuli crossbred steers. , 1999, Journal of animal science.

[12]  J A Nienaber,et al.  Livestock production system management responses to thermal challenges , 2007, International journal of biometeorology.

[13]  T. Mader,et al.  Effect of sprinkling on feedlot microclimate and cattle behavior , 2007, International journal of biometeorology.

[14]  N. Lacetera,et al.  Response of Domestic Animals to Climate Challenges , 2009 .

[15]  T. Brown-Brandl,et al.  Dynamic Response Indicators of Heat Stress in Shaded and Non-shaded Feedlot Cattle, Part 2: Predictive Relationships , 2005 .

[16]  D. Ames,et al.  Wind-Chill effect for cattle and sheep. , 1975, Journal of animal science.

[17]  David C. Nielsen,et al.  Automated Weather Data Network for Agriculture , 1983 .

[18]  T. Mader,et al.  Wind protection effects and airflow patterns in outside feedlots. , 1997, Journal of animal science.

[19]  G. Hahn Dynamic responses of cattle to thermal heat loads. , 1999, Journal of animal science.

[20]  E. C. Thom The Discomfort Index , 1959 .

[21]  T. Mader,et al.  Effect of management strategies on reducing heat stress of feedlot cattle: feed and water intake. , 2004, Journal of animal science.

[22]  M. L. Riedesel,et al.  Principles of Integrative Environmental Physiology , 2002 .

[23]  T. Brown-Brandl,et al.  Heat stress risk factors of feedlot heifers , 2006 .

[24]  H. C. Rowsell,et al.  A Guide to Environmental Research on Animals , 1972 .

[25]  T. E. Bond,et al.  Solar, Atmospheric, and Terrestrial Radiation Received by Shaded and Unshaded Animals , 1967 .

[26]  P. Siple,et al.  Measurements of dry atmospheric cooling in subfreezing temperatures , 1945 .

[27]  T. Mader,et al.  Strategies to reduce feedlot cattle heat stress: effects on tympanic temperature. , 2003, Journal of animal science.

[28]  T. Mader,et al.  Effects of growth-promoting agents and season on yearling feedlot heifer performance. , 2004, Journal of animal science.

[29]  T. Mader,et al.  Shade and wind barrier effects on summertime feedlot cattle performance. , 1999, Journal of animal science.

[30]  B. Olson,et al.  Thermal balance of cattle grazing winter range: model application. , 2006, Journal of animal science.

[31]  R. Rasby,et al.  Environmental effects on pregnancy rate in beef cattle. , 2006, Journal of animal science.